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Published in final edited form as: Structure. 2024 Jun 10;32(8):1231–1238.e4. doi: 10.1016/j.str.2024.05.010

An expanded trove of fragment-bound structures for the allosteric enzyme PTP1B from computational reanalysis of large-scale crystallographic data

Tamar Mehlman 1,2, Helen M Ginn 3,4,5, Daniel A Keedy 1,6,7,8,#
PMCID: PMC11316629  NIHMSID: NIHMS2000979  PMID: 38861991

Summary

Due to their low binding affinities, detecting small-molecule fragments bound to protein structures from crystallographic datasets has been a challenge. Here we report a trove of 65 new fragment hits for PTP1B, an “undruggable” therapeutic target enzyme for diabetes and cancer. These structures were obtained from computational analysis of data from a large crystallographic screen, demonstrating the power of this approach to elucidate many (~50% more) “hidden” ligand-bound states of proteins. Our new structures include a fragment hit found in a novel binding site in PTP1B with a unique location relative to the active site, one that links adjacent allosteric sites, and, perhaps most strikingly, a fragment that induces long-range allosteric protein conformational responses. Altogether, our research highlights the utility of computational analysis of crystallographic data, makes publicly available dozens of new ligand-bound structures of a high-value drug target, and identifies novel aspects of ligandability and allostery in PTP1B.

eTOC Blurb

Mehlman et al. report 65 new small-molecule fragment hits for PTP1B, an “undruggable” therapeutic target enzyme for diabetes and cancer. These structures were obtained from computational analysis of data from a large crystallographic screen, demonstrating the power of this approach to elucidate many (~50% more) “hidden” ligand-bound states of proteins.

Graphical Abstract:

graphic file with name nihms-2000979-f0001.jpg

Introduction

Rational allosteric modulation of protein function is a daunting task. To address this challenge, crystallographic small-molecule fragment screening is emerging as a powerful method to rapidly identify chemical footholds at many surface sites. An advantage of fragment screening using X-ray crystallography, as opposed to using other biophysical methods, is that it yields fully atomistic models of each fragment hit bound to the protein, which are useful for structure-based drug design of compounds that may allosterically influence distal functional sites 1. Crystallographic fragment screening has been used in recent years for a variety of proteins of significant biomedical interest, leading to dozens if not hundreds of hits in each case 27.

One such protein is PTP1B, the archetypal protein tyrosine phosphatase 8 and a highly validated therapeutic target for several human diseases including diabetes, breast cancer, and Rett syndrome 913. Previously, a large crystallographic fragment screen was performed for PTP1B: from 1966 datasets spanning 1627 unique fragments, 143 bound fragment hits across 110 structures were identified 2. That work leveraged an early version of the PanDDA algorithm 14, which exploited the density variation of ligand-soaked protein crystals, in bound and unbound states, to isolate electron density “event maps” for the ligand-bound state that enable structural modeling.

However, although it attempts to correct for global dissimilarities between structures via local real-space map alignments, PanDDA relies on a substantial degree of isomorphism between crystals to identify fragment hits 14. Subsequent to the original PTP1B screen 2, a new computational method called cluster4x was introduced for pre-clustering datasets using a combination of structure factors in reciprocal space and model Cα displacements in real space 15. A reanalysis of the original PTP1B fragment screen datasets using cluster4x revealed clustering into 17 clusters; subsequent PanDDA analyses for each cluster of datasets yielded evidence for 75 more total fragment hits, representing a substantial +52% increase in hit rate from the same data 15. The clustering was especially prevalent for PTP1B as opposed to other (albeit smaller) fragment screens analyzed in that study. Clustering has also since been employed in a number of studies, namely a drug screen on SARS-CoV-2 main protease 5, papain-like protease 16, and NSP15 endoribonuclease 17, and for fragment screens employing the F2X-Entry or F2X-Universal Library of fragments against the Prp8 RNaseH-like domain and snRNP assembly factor Aar2 18. For our subsequent rescreen of a subset of the original PTP1B fragment hits at room temperature (RT) instead of cryogenic (cryo) temperature 2,1923, pre-clustering with cluster4x yielded 5 more hits (+56% increase) 3, further emphasizing the importance of pre-clustering fragment screen data. Unfortunately, although the overall statistics of putative additional hits from the cluster4x analysis of the original large screen of PTP1B were reported 15, new structural models and maps were not refined, published, or further interrogated — leaving untapped a vast resource of potential insights for a biomedically important protein system.

To address this gap, here we have modeled, refined, and analyzed 59 new crystal structures of PTP1B in complex with 65 new fragment hits, representing +54% and +46% increases respectively over the original study 2. This trove of new structures is now for the first time available to the public in the Protein Data Bank (PDB) 24, where they may be of service to those interested in phosphatase drug design and/or basic biology.

Using this wealth of data, we report several useful insights into ligandability and allosteric susceptibilities in this dynamic enzyme. Despite the seemingly thorough coverage of the protein surface with the original hits 2, with the new hits we observe novel binding sites, including one which has since been validated by molecular dynamics simulations and crystallography 25. Some other new hits uniquely bridge previously reported allosteric sites that are nearby in the structure, offering potential to develop synergistic allosteric modulators. Even when they bind in the same site as previous hits, the new fragment hits are chemically distinct, and include moieties that explore distinct structural subpockets. Intriguingly, we also identify a new fragment that provokes a previously unreported allosteric response along an internal conduit, which involves a recently reported functionally linked motif 26,27.

Results

New fragment hits from pre-clustering of X-ray datasets

To obtain dozens of previously unmodeled ligand binding events for PTP1B, we reexamined the original large-scale crystallographic small-molecule fragment screen of PTP1B 2. Specifically, we examined the results of a computational reanalysis of those data using the new pre-clustering software cluster4x 15 upstream of PanDDA analysis 14. The pre-clustering analysis had yielded an additional 75 putative new hits (across 72 structures), ranging from 0–14 new hits per cluster 15.

We reexamined the PanDDA Z-maps and event maps 14 from the pre-clustering analysis 15. Most of these maps from the pre-clustered data provide strong evidence for the presence of the soaked fragment (Fig. S1). Guided by these maps, we confidently modeled 65 hits (across 59 structures) out of the 75 putative new hits (across 72 structures). This resulted in a +46% increase in hits (+54% increase in structures with hits) from an already high total of 143 hits (across 110 datasets). Of the 65 modeled new hits, 50 were not originally flagged as PanDDA events; thus pre-clustering was key to identifying these hits.

Additionally, a comparison of the real-space correlation coefficient (RSCC) values for the small-molecule fragments in the traditional 2FoFc maps, the original PanDDA event maps, and the post-cluster4x event maps indicated that the event maps had better RSCC values than 2FoFc maps in nearly all cases (Table S1, Fig. S2AB). Furthermore, there was an overall improvement of the RSCC values in the post-cluster4x event maps relative to the original event maps (Fig. S2C). This is consistent with visual improvements seen in the cluster4x Z-maps in the prior cluster4x analysis 15.

The 59 new fragment hit structures had favorable resolutions and Rfree values (Fig. S3). We have performed model validation, refinement (Table S2), and deposition to the Protein Data Bank for the new structures, where they are now publicly available to the broader community of scientists interested in phosphatase basic biology, drug discovery, and developing computational methods for modeling protein-ligand interactions.

Overview of new fragment hits

Our new fragment hits are distributed across 13 distinct binding sites in PTP1B (Fig. 1, Fig. 2A). They have a similar distribution as the original cryogenic-temperature hits 2 (Fig. 1, Fig. 2B) and the subsequent hits from two room-temperature screens 3 (Fig. S4, Fig. S5). Many of the new hits localize to the three previously allosteric “hotspots”: the BB site, L16 site, and 197 site 2. No new hits bind in the active site; this is consistent with a low number of hits for the active site in the original screen 2, and likely is related to the charged nature of the active site and general apolar nature of the fragments. Some of our new cryo hits localize to sites that were not bound at RT (albeit with smaller fragment libraries at RT 3); conversely, some RT hits are at sites with no new cryo hits (Fig. S4, Fig. S5).

Figure 1: Overview of new fragment hits across binding sites.

Figure 1:

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Overview of fragment hits from original cryogenic-temperature screen 2 and new hits reported in this study. Key sites in PTP1B, including three allosteric sites and the active site, are annotated. NB: site numbers do not coincide with previous site numbering 2. See also Fig. S4.

Figure 2: Structural overview of small-molecule fragment hits for PTP1B.

Figure 2:

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A. The new fragment hits reported here (cyan) span several major binding hotspots and functional sites (green, orange, purple, and red) across the surface of PTP1B.

B. Same as panel b, but with structures from the original cryogenic-temperature screen 2 (blue) overlaid.

See also Fig. S5.

New binding sites in PTP1B

The new fragment hits we report here include two new binding sites in PTP1B that were not previously seen in the original cryogenic screen or the subsequent RT screens (Fig. 3A). The first of these new sites is located “on top of” the catalytic WPD loop, next to the E loop (Fig. 3B). To our knowledge, no previous small-molecule ligands have been shown to bind to this area of PTP1B, including fortuitous “accessory ligands” such as ordered buffer components or cryoprotectants. There is a crystal contact somewhat nearby, but there is no direct crystal contact to the fragment binding site, suggesting it may also be bindable in solution. Motions of the WPD loop are critical for enzyme catalysis in PTP1B 28, and the WPD loop and E loop have been shown to exhibit correlated motions in the homolog HePTP 29, so the new binding site we report may be of interest for subsequent inhibitor development.

Figure 3: Novel binding sites in PTP1B identified from new fragment hits.

Figure 3:

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Fragment hits at binding sites that were not seen in previous fragment screens of PTP1B at cryo or RT.

A. Overview of binding locations. Same viewing angle and functional site coloring as Fig. 2, left panels.

B. PDB ID 7GTQ (y0241). The fragment sits between the WPD loop (red) and E loop (yellow).

C. PDB ID 7GTR, 7GTV (y0346, y1875). Crystal structures of PTP1B DES-4799 fragment series characterized by molecular dynamics simulations (PDB ID: 8g65, 8g68, 8g69) 25 (pale green, transparent). STEP allosteric activators (PDB ID: 6h8r, 6h8s) 30 (pink, transparent) are shown for context.

The second new site, with two partially overlapping new fragment hits, is located adjacent to the S loop, distal from the active site (Fig. 3C). Several ordered cryoprotectant molecules are also modeled in this site in other PTP1B structures, supporting its ligandability. After publication of the cluster4x reanalysis paper that first identified the new fragment hits reported here 15, another fragment (DES-4799) was also found to bind to this site in several poses by long-timescale molecular dynamics simulations, which, along with two analogs, was confirmed by X-ray crystallography 25 (Fig. 3C). Thus, those simulations and crystal structures provided post-facto validation of our new hits from computational reanalysis of crystallographic fragment screening data, and vice versa. Our new fragment hits and the DES-4799 series have different chemical moieties that protrude in distinct directions within the binding pocket, suggesting that medicinal chemistry efforts may fruitfully combine features of both to enhance binding at this site. Notably, these fragment poses for PTP1B also partially overlap with poses of small-molecule allosteric activators for the homolog STEP bound to the S loop region 30 (Fig. 3C), hinting at possible allosteric potential at this site in PTP1B as well.

Increased structural and chemical diversity

The new fragment hits increase the diversity of ligand coverage of the surface of PTP1B in several distinct ways. First, some new hits bridge neighboring sites in unique ways. For example, one new hit spans two neighboring fragment-binding hotspots which are both key allosteric sites: the BB site 2,31 and L16 site 2,27,32 (Fig. 4A). It does so by wedging under the C-terminus of the α6 helix, which segues directly to the quasi-disordered, allosteric α7 helix 2,33,34. This observation raises the prospect of linking fragments, or preexisting allosteric inhibitors 31, in these two sites to modulate enzyme activity more potently.

Figure 4: Increased coverage within and between existing binding sites.

Figure 4:

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A. A new fragment hit (PDB ID 7GSA, y0288) bridges two fragment-binding hotspots in neighboring allosteric sites from the original cryo fragment hits: the BB site and the L16 site.

B. In another binding site, two new fragment hits (PDB ID 7GTG, y1718; PDB ID 7GSQ, y0847) bind in poses that place chemical groups in regions of the site that were unexplored by the original cryo fragment hits (arrows).

Second, some new hits extend structural coverage within known binding sites. For example, several new hits in a site near the α2 helix protrude in different directions relative to previous hits (Fig. 4B).

Third, some new hits bind to new sites in addition to the original sites. Several fragments illustrate this theme, including some with new hits detected in the same structure from the same diffraction dataset, and others with new hits detected in replicate structures from different crystals soaked with the same fragment (Fig. S6). While in each case the fragment was already known to be able to bind to PTP1B in at least one location, these additional hits increase the chemical diversity in each binding site.

Indeed, more generally, most of the new fragment hits we report here are chemically dissimilar from other previous fragment hits within each site, as quantified by Tanimoto scores (Fig. 5). The low Tanimoto scores likely arise from the general dissimilarity between fragments in fragment libraries due to their small size and low complexity, in contrast to e.g. congeneric series of close derivatives of related larger compounds as might be expected further downstream in a drug development pipeline. Overall, these observations show that our new fragment hits expand the structural and chemical diversity of known ligands at many sites across the surface of PTP1B.

Figure 5: New fragment hits increase chemical diversity per binding site.

Figure 5:

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A. Lowest Tanimoto score per site of any new hit to any previous cryo hit from the original screen 2, illustrating the extent to which the new hits represent distinct chemical scaffolds at many sites in the protein. Boxes represent the interquartile range (IQR), orange lines represent the median, whiskers represent 1.5x the IQR, and points are outliers beyond the whiskers.

B. Chemical structure of an example new hit (PDB ID 7GTF, y1532) compared to all the previous hits in the same site (site 12), with the Tanimoto score below each.

Novel protein response along an allosteric conduit

In one of our new structures, we observe unanticipated conformational changes spanning 23 Å from a distal fragment binding site to the active-site WPD loop (Fig. 6). At the fragment site, a surface loop shifts by 0.5 Å, and a series of side chains respond in concert to the presence of the fragment. This includes the side chain of Cys226, which is immediately adjacent to Phe225 in the α4 helix, a recently discovered allosteric hub in PTP1B that we and others have recently interrogated 26,27; in particular, mutation of Phe225 and nearby residues surprisingly leads to increased enzyme activity 26, which involves the population of additional alternate conformations for several residues in this region 27. Contacting α4, the α6 helix undergoes a concerted 0.5 Å backbone shift in response to the fragment, which is coupled to closure of the adjacent catalytic WPD loop.

Figure 6: New fragment hit induces protein conformational response along allosteric conduit.

Figure 6:

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A. Overview of pathway from fragment binding site to active site in PDB ID 7GTT (y0711), including ground state (gray) and bound state (cyan), with key structural elements labeled.

B. Zoom-in to fragment binding site, showing conformational changes of nearby loop and series of side chains; supported by alternating difference peaks in Z-map, contoured at +/− 3 σ (green/red).

C. Zoom-in to active-site WPD loop, showing shift to closed state (cyan); supported by event map, contoured at 1.5 σ.

There is no density evidence for oxidation of the catalytic Cys215 in the active site, arguing against the notion that chemical modification unrelated to distal fragment binding causes the WPD loop to close. Compared to the other 15 fragment hits in this site, including 10 from the original study and 5 new hits reported here, only this fragment appeared to elicit an allosteric response; the difference may be driven by the fact that this fragment protrudes the most toward the mobile loop and Met74. Taken together, we interpret these observations as allosteric response by PTP1B to a new fragment hit at a site not previously reported as allosteric, which integrates into the α-helical bundle of the tertiary structure as with other allosteric sites in this protein 2, but in a distinct way.

Discussion

Crystallographic fragment screening is rapidly emerging as a powerful and accessible technique for efficiently mapping the ligandability of proteins of biomedical interest 27. Indeed, since the PanDDA method for leveraging multiple datasets to identify low-occupancy bound states was introduced in 2017 14, structures from fragment screens constitute a substantial fraction (>6%) of new ligand-bound crystal structures in the Protein Data Bank. We anticipate that this proportion will only grow in the coming years, as experimental workflows at synchrotrons become more user-friendly and accessible and computational methods for bound fragment hit detection and modeling continue to mature.

One such computational advance is cluster4x 15, which yielded a substantial increase in fragment hits from pre-existing crystallographic fragment screen data for the therapeutic target enzyme PTP1B. Per our analysis here, cluster4x yielded 65 modelable new hits (across 59 datasets), a substantial +46% increase (+54%) over the original 143 hits (across 110 datasets). Most of these new hits bind in sites that had other fragments bound among the original hits, suggesting that, in a sense, the ligandable space of this protein had already neared saturation. However, with these new hits, we identify two new binding sites (one of which has since also been validated by another structure), one new hit that uniquely bridges neighboring allosteric sites in enticing fashion, and many new hits that explore distinct subregions of various binding sites in previously unseen ways.

In addition, with several different fragments that bind at the same non-orthosteric site, the PanDDA event maps reveal an unanticipated protein conformational response along an intramolecular pathway linking the binding site to the enzyme active site. Intriguingly, this pathway involves residues recently shown to influence catalytic function: mutations to these residues identified from coevolutionary analysis increase catalysis and decrease stability 26,27. These observations suggest the enticing possibility of allosteric communication between the distal binding site we highlight and the dynamic active site, ~23 Å away. Our findings thus motivate subsequent fragment-based design 1,35 of higher-affinity binders at this site that may allosterically modulate function, underscoring the concept of mutations as a paradigm for drug discovery.

The 59 new ligand-bound structures of PTP1B we report here, obtained from computational reanalysis of existing experimental fragment screening data, constitute many-fold more structural information than is seen in the vast majority of publications about protein-ligand interactions. This is useful, as the rapidly emerging set of deep learning methods for protein-ligand docking and ligand design benefit from larger training sets of experimental protein-ligand structures 3638; crystallographic fragment screening and improved hit detection could benefit these endeavors. On a larger scale, pharmaceutical companies house private databases that collectively contain many thousands of protein-ligand crystal structures; although making these available to developers of deep learning methods would pose a significant logistical challenge, the potential benefits to society are substantial 37. Other smaller-scale but practically important matters also warrant attention in this realm, including the optimal treatment of ensembles consisting of both ligand-bound and unbound states 39 and the need to shift away from the traditional PDB model format as the pool of unique three-letter ligand codes will soon be depleted.

Finally, all the structures we report here, and ~94% of experimental protein-ligand crystal structures to date, are based on diffraction data collected at cryogenic temperature (<100 K). By contrast, proteins adopt distinct conformational ensembles at room temperature or physiological temperature 2,1923,32,40. Importantly, so do ligands bound to proteins 3,41,42. The potential impact of this widespread bias in the training data for current deep learning methods for modeling protein-ligand interactions 3638 or protein structures more generally 4345 remains to be explored.

STAR Methods

Resource Availability

Lead Contact

Further information and requests for resources and reagents should be directed to and will be fulfilled by the lead contact, Daniel Keedy (dkeedy@gc.cuny.edu).

Materials Availability

This study did not generate any new unique reagents.

Data and Code Availability

  • Bound-state models, structure factors, PanDDA event maps, and traditional maps (2Fo-Fc and Fo-Fc) for all fragment-bound structures are available in the Protein Data Bank and the accession codes are summarized in Table S3 and in the key resources table. In addition, we provide a Zenodo directory containing cluster identities and dataset assignments, all bound-state models, all event maps, identifying information for all fragments, and related details at https://doi.org/10.5281/zenodo.10455980.

  • This paper does not report original code.

  • Any additional information required to reanalyze the data reported in this paper is available from the lead contact upon request.

Key resources table.
REAGENT or RESOURCE SOURCE IDENTIFIER
Deposited data
Analyzed density maps and models This paper 10.5281/zenodo.10455979
PTP1B in complex with FMOPL000466a This paper PDB: 7GS7
PTP1B in complex with FMOPL000631a This paper PDB: 7GS8
PTP1B in complex with FMOPL000260a This paper PDB: 7GS9
PTP1B in complex with FMOPL000438a This paper PDB: 7GSA
PTP1B in complex with FMOPL000729a This paper PDB: 7GSB
PTP1B in complex with FMOPL000605a This paper PDB: 7GSC
PTP1B in complex with FMOPL000383a This paper PDB: 7GSD
PTP1B in complex with FMOPL000421a This paper PDB: 7GSE
PTP1B in complex with FMOPL000316a This paper PDB: 7GSF
PTP1B in complex with FMOPL000530a This paper PDB: 7GSG
PTP1B in complex with XST00000046b This paper PDB: 7GSH
PTP1B in complex with FMOPL000543a This paper PDB: 7GSI
PTP1B in complex with FMOPL000279a This paper PDB: 7GSJ
PTP1B in complex with FMSOA000274b This paper PDB: 7GSK
PTP1B in complex with XST00000437b This paper PDB: 7GSL
PTP1B in complex with XST00000519b This paper PDB: 7GSM
PTP1B in complex with FMOMB000029a This paper PDB: 7GSN
PTP1B in complex with FMOMB000149a This paper PDB: 7GSO
PTP1B in complex with XST00000055b This paper PDB: 7GSQ
PTP1B in complex with FMOMB000056a This paper PDB: 7GSR
PTP1B in complex with FMOPL000382a This paper PDB: 7GST
PTP1B in complex with FMSOA000830b This paper PDB: 7GSU
PTP1B in complex with XST00000422b This paper PDB: 7GSV
PTP1B in complex with FMSOA001440b This paper PDB: 7GSW
PTP1B in complex with FMSOA001175b This paper PDB: 7GSX
PTP1B in complex with FMSOA000686b This paper PDB: 7GSY
PTP1B in complex with FMOMB000275a This paper PDB: 7GSZ
PTP1B in complex with FMOMB000209a This paper PDB: 7GT0
PTP1B in complex with XST00000752b This paper PDB: 7GT1
PTP1B in complex with FMOOA000527a This paper PDB: 7GT2
PTP1B in complex with FMOOA000528a This paper PDB: 7GT3
PTP1B in complex with FMOOA000529a This paper PDB: 7GT4
PTP1B in complex with FMOOA000530a This paper PDB: 7GT5
PTP1B in complex with FMSOA001181b This paper PDB: 7GT6
PTP1B in complex with FMSOA001439b This paper PDB: 7GT7
PTP1B in complex with FMSOA000463b This paper PDB: 7GT8
PTP1B in complex with FMOMB000065a This paper PDB: 7GT9
PTP1B in complex with FMSOA000899b This paper PDB: 7GTA
PTP1B in complex with XST00001145b This paper PDB: 7GTB
PTP1B in complex with FMOMB000110a This paper PDB: 7GTC
PTP1B in complex with XST00000646b This paper PDB: 7GTD
PTP1B in complex with XST00000754b This paper PDB: 7GTE
PTP1B in complex with FMOOA000684a This paper PDB: 7GTF
PTP1B in complex with FMOOA000637a This paper PDB: 7GTG
PTP1B in complex with FMOOA000571a This paper PDB: 7GTH
PTP1B in complex with XST00000280c This paper PDB: 7GTI
PTP1B in complex with FMOOA000552a This paper PDB: 7GTJ
PTP1B in complex with FMOOA000554a This paper PDB: 7GTK
PTP1B in complex with FMOOA000543a This paper PDB: 7GTL
PTP1B in complex with FMOOA000625a This paper PDB: 7GTM
PTP1B in complex with FMOOA000602a This paper PDB: 7GTN
PTP1B in complex with FMOPL000688a This paper PDB: 7GTO
PTP1B in complex with FMOPL000311a This paper PDB: 7GTP
PTP1B in complex with FMOPL000587a This paper PDB: 7GTQ
PTP1B in complex with FMOPL000604a This paper PDB: 7GTR
PTP1B in complex with FMOPL000148a This paper PDB: 7GTS
PTP1B in complex with FMOMB000297a This paper PDB: 7GTT
PTP1B in complex with XST00000765c This paper PDB: 7GTU
PTP1B ground state cluster1 This paper PDB: 7GTV
PTP1B ground state cluster2 This paper PDB: 7GTW
PTP1B ground state cluster3 This paper PDB: 7GTX
PTP1B ground state cluster5 This paper PDB: 7GTY
PTP1B ground state cluster6 This paper PDB: 7GTZ
PTP1B ground state cluster7 This paper PDB: 7GU0
PTP1B ground state cluster8 This paper PDB: 7GU1
PTP1B ground state cluster9 This paper PDB: 7GU2
PTP1B ground state cluster11 This paper PDB: 7GU3
PTP1B ground state cluster12 This paper PDB: 7GU4
PTP1B ground state cluster14 This paper PDB: 7GU5
PTP1B ground state cluster15 This paper PDB: 7GU6
PTP1B ground state cluster16 This paper PDB: 7GU7
PTP1B ground state cluster17 This paper PDB: 7GU8
PTP1B ground state cluster18 This paper PDB: 7GU9
PTP1B ground state cluster19 This paper PDB: 7GUA
PTP1B ground state cluster20 This paper PDB: 7GUB
Software and algorithms
PanDDA Pearce et al.14 https://pandda.bitbucket.io/pandda/index.html
Cluster4x Ginn 15 https://snapcraft.io/cluster4x
Coot Emsley et al. 47 https://www.ccp4.ac.uk/
PyMOL Schrödinger 53 https://pymol.org/
Phenix Liebschner et al. 50 https://phenix-online.org/
REFMAC Murshudov et al. 51 https://www2.mrc-lmb.cam.ac.uk/groups/murshudov/
RDKit Landrum 52 https://www.rdkit.org/
eLBOW Moriarty et al. 48 https://phenix-online.org/documentation/reference/elbow.html
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Method Details

Dataset clustering and hit detection

A summary of the salient methods for the prior dataset clustering and hit detection 15 is as follows. Refined models and structure factors were obtained from the original cryogenic-temperature PTP1B crystallographic fragment screen 2 by downloading from Zenodo 46. Symmetry operations were adjusted per-model to ensure that all structures conformed to the same asymmetric unit. Structures exhibiting either implausibly high R values or no clear adherence to any identified cluster were excluded from the analysis. Clustering was carried out using cluster4x using human-guided separation on the Cα coordinates. The remaining hits formed 18 additional clusters: these consist of two sets of 9 paired clusters each, due to the Miller indexing ambiguity of (h,k,l) and (k,h,-l), which are randomly assigned during data reduction. In the previous study, all existing 110 hits separated into one pair of clusters due to the additional manual refinement of these structures which were used in the analysis. This is therefore equivalent to the common step of removing previous hits from the PanDDA run, to reduce the density variance in ligand-binding hotspots. For each cluster, Z-maps and event maps corresponding to potential ligand binding events were generated using PanDDA 14. This used the default parameterization for PanDDA but with a modification to reduce the minimum number of datasets to 20.

Structural modeling and refinement

To model and refine the initial bound-state models from the initial cluster4x paper 15, we reexamined the PanDDA maps in detail for each example.

Fragments and associated protein changes were modeled in Coot 47 (Fig. S1). Some models showed structural changes like loops closing, but no ligand was seen bound in the model, so the structures were not included in this analysis. Some new binding events were found within datasets that already had ligands modeled from the original screen; in these cases, both the new and previous ligands were modeled. We avoided modeling alternate conformations for ligands to minimize model complexity.

In some cases, we modeled the WPD closed but did not model α7 ordered or L16 closed; this should not necessarily be interpreted as evidence for allosteric de-coupling, but rather is indicative of the degree of clarity at the different local areas in the event maps, which can often be noisy in places.

Waters were kept the same between the unbound and bound models, except where the PanDDA event map indicated a shift, deletion, or an addition of a new water. Ligand restraints files were calculated with eLBOW 48.

Because ligands are not fully occupied, to prepare for refinement we must use an ensemble of bound state plus unbound state (i.e. ground state) for refinement 49. We generated such an ensemble model using the giant.merge_conformations script from PanDDA 1.0.0. We then added hydrogens with Phenix 50 ReadySet! Restraints, both between multi state occupancy groups and between local alternate locations, were generated using giant.make_restraint scripts from PanDDA 1.0.0. The argument ‘MAKE HOUT Yes’ was added to the Refmac restraint file to ensure the hydrogens were preserved.

For refinement of fragment-bound ensemble models, the published protocol for post-PanDDA refinement for deposition 49 was used, including the giant.quick_refine scripts from PanDDA 1.0.0 and the program Refmac 51. For a few examples, the script was rerun if the ligand was refined to a total occupancy greater than 1. Additionally, some hydrogens refined to 0 occupancy so they were manually edited to match the remainder of its residue. Refined bound-state models were then re-extracted using giant.split_conformations. Some examples were omitted where the ligand was not stable upon refinement. Final data processing and refinement statistics are available in Table S2.

Fragments were validated and scored using the giant.score_model script from PanDDA 1.0.0 to ensure the following five criteria were acceptable: real-space correlation coefficient (RSCC), real-space difference Z-score (RSZD), real-space observed Z-score (RSZO), ratio of ligand/protein B-factors (B-Ratio), and movement of ligand after refinement (RMSD). Outliers were removed, except some that were marginal that were visually inspected and found sufficiently supported by the density. For those with new hits in datasets that already had ligands modeled from the original screen, the original hits were kept for consistency even if their validation plots were marginal.

Model analysis and visualization

Tanimoto scores for Fig. 5 were calculated using RDKit 52 topological fingerprints, comparing the new cluster4x hits to the previous hits from the original cryo screen.

The phenix.real_space_correlation utility was used to calculate RSCC values (Table S1, Fig. S2). Prior to the RSCC inspection for new hits with original event maps, a PanDDA analysis was performed with the original inputs to obtain mean maps, then the pandda.generate_BDC_maps script was used to obtain custom “pseudo event maps” at 1-BDC values corresponding to the cluster4x hits. Custom scripting was used to adjust the flags in the event maps in preparation for the RSCC calculations.

PyMol was used to visualize models and electron density maps for generating figures 53.

Quantification and Statistical Analysis

X-ray data collection and refinement statistics are summarized in Table S2.

Supplementary Material

1
3
4
5

Highlights.

  • Computational analysis of crystallographic small-molecule fragment screen for PTP1B

  • Identification of 65 new fragment hits across 59 new liganded crystal structures

  • New fragments reveal novel aspects of ligandability and allostery in PTP1B

Acknowledgments

DAK is supported by NIH R35 GM133769.

HMG is supported by the Helmholtz Association, grant VH-NG-19-02 (Helmholtz Young Investigator Group).

We thank Jose Brandao-Neto and Justin Biel for help locating original data reduction log files and unmerged structure factor files. We also thank Conor Wild for his help in calculating RSCC values for custom PanDDA event maps.

Footnotes

Declaration of Interests

The authors declare no competing interests.

Excel files for the following tables are included in Supplementary Information:

Table S1: Real-space correlation coefficients (RSCC) for different map types; related to STAR Methods.

Table S2: Crystallographic statistics; related to STAR Methods.

Table S3: PDB accession codes; related to STAR Methods.

Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

1
NIHMS2000979-supplement-1.pdf (886.2KB, pdf)
3
NIHMS2000979-supplement-3.xlsx (30.3KB, xlsx)
4
NIHMS2000979-supplement-4.xlsx (29KB, xlsx)
5
NIHMS2000979-supplement-5.xlsx (11KB, xlsx)

Data Availability Statement

  • Bound-state models, structure factors, PanDDA event maps, and traditional maps (2Fo-Fc and Fo-Fc) for all fragment-bound structures are available in the Protein Data Bank and the accession codes are summarized in Table S3 and in the key resources table. In addition, we provide a Zenodo directory containing cluster identities and dataset assignments, all bound-state models, all event maps, identifying information for all fragments, and related details at https://doi.org/10.5281/zenodo.10455980.

  • This paper does not report original code.

  • Any additional information required to reanalyze the data reported in this paper is available from the lead contact upon request.

Key resources table.

REAGENT or RESOURCE SOURCE IDENTIFIER
Deposited data
Analyzed density maps and models This paper 10.5281/zenodo.10455979
PTP1B in complex with FMOPL000466a This paper PDB: 7GS7
PTP1B in complex with FMOPL000631a This paper PDB: 7GS8
PTP1B in complex with FMOPL000260a This paper PDB: 7GS9
PTP1B in complex with FMOPL000438a This paper PDB: 7GSA
PTP1B in complex with FMOPL000729a This paper PDB: 7GSB
PTP1B in complex with FMOPL000605a This paper PDB: 7GSC
PTP1B in complex with FMOPL000383a This paper PDB: 7GSD
PTP1B in complex with FMOPL000421a This paper PDB: 7GSE
PTP1B in complex with FMOPL000316a This paper PDB: 7GSF
PTP1B in complex with FMOPL000530a This paper PDB: 7GSG
PTP1B in complex with XST00000046b This paper PDB: 7GSH
PTP1B in complex with FMOPL000543a This paper PDB: 7GSI
PTP1B in complex with FMOPL000279a This paper PDB: 7GSJ
PTP1B in complex with FMSOA000274b This paper PDB: 7GSK
PTP1B in complex with XST00000437b This paper PDB: 7GSL
PTP1B in complex with XST00000519b This paper PDB: 7GSM
PTP1B in complex with FMOMB000029a This paper PDB: 7GSN
PTP1B in complex with FMOMB000149a This paper PDB: 7GSO
PTP1B in complex with XST00000055b This paper PDB: 7GSQ
PTP1B in complex with FMOMB000056a This paper PDB: 7GSR
PTP1B in complex with FMOPL000382a This paper PDB: 7GST
PTP1B in complex with FMSOA000830b This paper PDB: 7GSU
PTP1B in complex with XST00000422b This paper PDB: 7GSV
PTP1B in complex with FMSOA001440b This paper PDB: 7GSW
PTP1B in complex with FMSOA001175b This paper PDB: 7GSX
PTP1B in complex with FMSOA000686b This paper PDB: 7GSY
PTP1B in complex with FMOMB000275a This paper PDB: 7GSZ
PTP1B in complex with FMOMB000209a This paper PDB: 7GT0
PTP1B in complex with XST00000752b This paper PDB: 7GT1
PTP1B in complex with FMOOA000527a This paper PDB: 7GT2
PTP1B in complex with FMOOA000528a This paper PDB: 7GT3
PTP1B in complex with FMOOA000529a This paper PDB: 7GT4
PTP1B in complex with FMOOA000530a This paper PDB: 7GT5
PTP1B in complex with FMSOA001181b This paper PDB: 7GT6
PTP1B in complex with FMSOA001439b This paper PDB: 7GT7
PTP1B in complex with FMSOA000463b This paper PDB: 7GT8
PTP1B in complex with FMOMB000065a This paper PDB: 7GT9
PTP1B in complex with FMSOA000899b This paper PDB: 7GTA
PTP1B in complex with XST00001145b This paper PDB: 7GTB
PTP1B in complex with FMOMB000110a This paper PDB: 7GTC
PTP1B in complex with XST00000646b This paper PDB: 7GTD
PTP1B in complex with XST00000754b This paper PDB: 7GTE
PTP1B in complex with FMOOA000684a This paper PDB: 7GTF
PTP1B in complex with FMOOA000637a This paper PDB: 7GTG
PTP1B in complex with FMOOA000571a This paper PDB: 7GTH
PTP1B in complex with XST00000280c This paper PDB: 7GTI
PTP1B in complex with FMOOA000552a This paper PDB: 7GTJ
PTP1B in complex with FMOOA000554a This paper PDB: 7GTK
PTP1B in complex with FMOOA000543a This paper PDB: 7GTL
PTP1B in complex with FMOOA000625a This paper PDB: 7GTM
PTP1B in complex with FMOOA000602a This paper PDB: 7GTN
PTP1B in complex with FMOPL000688a This paper PDB: 7GTO
PTP1B in complex with FMOPL000311a This paper PDB: 7GTP
PTP1B in complex with FMOPL000587a This paper PDB: 7GTQ
PTP1B in complex with FMOPL000604a This paper PDB: 7GTR
PTP1B in complex with FMOPL000148a This paper PDB: 7GTS
PTP1B in complex with FMOMB000297a This paper PDB: 7GTT
PTP1B in complex with XST00000765c This paper PDB: 7GTU
PTP1B ground state cluster1 This paper PDB: 7GTV
PTP1B ground state cluster2 This paper PDB: 7GTW
PTP1B ground state cluster3 This paper PDB: 7GTX
PTP1B ground state cluster5 This paper PDB: 7GTY
PTP1B ground state cluster6 This paper PDB: 7GTZ
PTP1B ground state cluster7 This paper PDB: 7GU0
PTP1B ground state cluster8 This paper PDB: 7GU1
PTP1B ground state cluster9 This paper PDB: 7GU2
PTP1B ground state cluster11 This paper PDB: 7GU3
PTP1B ground state cluster12 This paper PDB: 7GU4
PTP1B ground state cluster14 This paper PDB: 7GU5
PTP1B ground state cluster15 This paper PDB: 7GU6
PTP1B ground state cluster16 This paper PDB: 7GU7
PTP1B ground state cluster17 This paper PDB: 7GU8
PTP1B ground state cluster18 This paper PDB: 7GU9
PTP1B ground state cluster19 This paper PDB: 7GUA
PTP1B ground state cluster20 This paper PDB: 7GUB
Software and algorithms
PanDDA Pearce et al.14 https://pandda.bitbucket.io/pandda/index.html
Cluster4x Ginn 15 https://snapcraft.io/cluster4x
Coot Emsley et al. 47 https://www.ccp4.ac.uk/
PyMOL Schrödinger 53 https://pymol.org/
Phenix Liebschner et al. 50 https://phenix-online.org/
REFMAC Murshudov et al. 51 https://www2.mrc-lmb.cam.ac.uk/groups/murshudov/
RDKit Landrum 52 https://www.rdkit.org/
eLBOW Moriarty et al. 48 https://phenix-online.org/documentation/reference/elbow.html
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RESOURCES